Acute study of dose-dependent effects of (−)-epicatechin on vascular function in healthy male volunteers: A randomized controlled trial

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Clinical Nutrition xxx (xxxx) xxx

55 56 57 58 59 60 61 journal homepage: http://www.elsevier.com/locate/clnu 62 63 Randomized Control Trials 64 65 66 67 68 69 ~o  n a, b, *, 1, S.M. Castle b, 1, G. Serra b, A. Le  ve ques c, L. Poquet c, L. Actis-Goretta d, M.E. Alan 70 71 J.P.E. Spencer b 72 a Regional Institute for Applied Scientific Research (IRICA), Area of Food Science and Technology, University of Castilla-La Mancha, Avd. Camilo Jos e Cela 10, 73 13071, Ciudad Real, Spain b 74 Department of Food and Nutritional Sciences, School of Chemistry, Food and Pharmacy, University of Reading, PO Box 226, RG2 6AP, Reading, United 75 Kingdom c Nestl e Research, 1026 Lausanne, Switzerland 76 d Nestl e Research, Singapore Hub, 138567, Singapore 77 78 79 a r t i c l e i n f o s u m m a r y 80 81 Article history: Background & aims: There is convincing clinical evidence to suggest that flavanol-containing foods/ 82 Received 19 December 2018 beverages are capable of inducing improvements in human vascular function. However, whilst 83 Accepted 28 March 2019 (
)-epicatechin has been tested for efficacy, a full dose-dependency has yet to be established, particu84 larly at doses below 1 mg/kg BW. The current study examined the dose-dependent effects of (
)-epi85 Keywords: catechin on human vascular function with concurrent measurement of plasma (
)-epicatechin (
)-Epicatechin 86 metabolites and levels of circulating nitrite and nitrate species, NOx. Acute study 87 Methods: An acute, double-blind, placebo-controlled, crossover intervention trial was conducted in 20 Vascular function 88 healthy males with 4 treatment arms: water-based (
)-epicatechin (0.1, 0.5 and 1.0 mg/kg BW) and a Dose effect 89 water only as control. Vascular function was assessed by flow-mediated dilatation (FMD) measured at the FMD brachial artery, laser Doppler imaging with iontophoresis (LDI) at the subcutaneous capillaries of the 90 forearm (response to Ach and SNP) and peripheral blood pressure (BP) at baseline, 1, 2, 4 and 6 h post91 intervention. Plasma analysis of epicatechin metabolites was conducted by LC-MS and circulating plasma 92 of nitrite and nitrate species were performed using an HPLC-based system (ENO-30). 93 Results: Significant increases in % FMD were found to occur at 1 and 2 h following intake of 1 mg/kg BW, 94 and at 2 h for the 0.5 mg/kg BW intake. There were no significant changes in LDI or BP at any time-points 95 or intake levels. Increases in FMD over the 6 h timeframe were closely paralleled by the appearance of 96 total plasma (
)-epicatechin metabolites. Non-significant changes in circulating NOx was observed. 97 Conclusions: Our data add further evidence that (
)-epicatechin is a causal vasoactive molecule within 98 flavanol-containing foods/beverages. In addition, we show for the first time that intake levels as low as 99 0.5 mg/kg BW are capable of inducing acute improvements in vascular function (FMD) in healthy volunteers. 100 © 2019 Published by Elsevier Ltd. 101 102 103 104 105 106 including at the population level, in a growing number of human 1. Introduction 107 intervention trials [1e6]. Recent dietary interventions in humans 108 have substantiated epidemiological data on an inverse relationship Cocoa is a rich source of flavanols which has been extensively 109 between flavanol cocoa intake and the risk of cardiovascular disinvestigated for its impact on vascular health at a number of levels, 110 eases. Various flavanol-mediated bioactivities after cocoa con111 sumption have enhance the endothelial function and vascular tone 112 of “at risk” and “healthy” individuals by means of increasing flow113 * Corresponding author. Regional Institute for Applied Scientific Research (IRICA), mediated dilation (FMD) of the brachial artery, lowering arterial Q1 Area of Food Science and Technology, University of Castilla-La Mancha, Avd. Camilo 114 blood pressure or increasing the circulating pool of nitric oxide  Cela 10, 13071, Ciudad Real, Spain. Jose 115 [7e16]. ~o n). E-mail address: [email protected] (M.E. Alan 116 1 Both authors contributed equally to this work. 117 118 https://doi.org/10.1016/j.clnu.2019.03.041 119 0261-5614/© 2019 Published by Elsevier Ltd. Contents lists available at ScienceDirect

Clinical Nutrition

Q4 Q3

Acute study of dose-dependent effects of (
)-epicatechin on vascular function in healthy male volunteers: A randomized controlled trial

~o  n ME et al., Acute study of dose-dependent effects of (
)-epicatechin on vascular function in healthy male Please cite this article as: Alan volunteers: A randomized controlled trial, Clinical Nutrition, https://doi.org/10.1016/j.clnu.2019.03.041

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~o n et al. / Clinical Nutrition xxx (xxxx) xxx M.E. Alan

Despite these datasets, a full understanding of the causality between components of cocoa and human vasoactivity remains to be established. The reasons for these shortcomings are, at least in part, based on the fact that food matrices contain a multitude of phytochemical constituents of which an unknown number may exert physiological effects. The main flavanols of cocoa are specially epicatechin, catechin and their oligomeric derivatives known as procyanidins. Flavanol monomers are vastly more well-studied than the oligomers and polymers due to a variety of factors: i) availability in isolated, purified form, ii) ease of qualitative and quantitative characterization, and iii) significantly greater bioavailability. However, there are little data on the systemic bioactivities of the larger forms, which are not necessarily less active than the monomers and consequently, they should not be excluded as key contributors to cocoa bioactivities. The chiral nature of monomeric flavanols should be noted since the bioactivity of flavanols is significantly influenced by the (þ)/(
) stereochemical configuration. Among them, (
)-epicatechin is thought to be the most likely physiologically active compound responsible for the vascular health benefits associated with cocoa since the oral administration of (
)-epicatechin produced a vascular response nearly six times higher than that of (
)-catechin [17]. Therefore, subsequent human intervention trials were focused on the elucidation of the casual vascular effects after human ingestion of (
)-epicatechin. From an acute study conducted with healthy male adults emanated that the oral administration of chemically highly purified (
)-epicatechin closely emulated acute vascular effects of flavanolrich cocoa [18]. All individuals had significantly increased the peripheral arterial tonometry index and the FMD at two hours after (
)-epicatechin ingestion at doses of 1 or 2 mg/kg of body weight, potentially through induction of an NO-mediated pathway [18]. Controversially, other controlled, double-masked, crossover study in humans concluded that although (
)-epicatechin intake increased flow-mediated arterial dilation, this outcome did not reach statistical significance disproving the health benefits of (
)-epicatechin [19]. Some authors disproved this statement due to the heterogeneity in vascular status of the study population, especially considering the small total number of participants of whom 22% would be considered as hypertensive [20]. This fact should not be overlooked and unappreciated due to its impact on outcomes and final interpretations which could mask meaningful conclusions. Therefore, due to the controversy regarding to the physiological effect of (
)-epicatechin, further research including reliable clinical trials with appropriate population should be conducted to address its potential health benefits. On the other hand, the minimum effective dose of (
)-epicatechin to induce significant physiological effects is another important remaining challenge which should be addressed. For that reasons, the current trial investigates the impact of 3 intake levels of highly purified (
)-epicatechin, 0.1, 0.5 and 1.0 mg/ kg on human vascular function over a 6 h period, primarily by assessment of flow-mediated dilatation (FMD). The effect of (
)-epicatechin on microvascular vasodilation was also assessed by lasser Doppler imaging which measured responses to cutaneous perfusion with an endothelium-dependent vasodilator (acetylcholine chloride, Ach) generating NO but also with an endothelium-independent vasodilator (sodium nitroprusside, SNP) since some microvascular responses have been demonstrated to be via endothelium-independent pathway [21]. In addition, plasma concentrations of nitrite and nitrate were also evaluated. The study was designed to objectively elucidate the minimum effective dose and timeframe at which improvements in macro- and microvascular vasodilation are observed in response to highly purified (
)-epicatechin intake.

2. Volunteers and methods 2.1. Clinical trial ethics The clinical study was conducted in line with the guidelines in the Declaration of Helsinki and study protocols were approved by the University of Reading Research Ethics Committee, UK (reference: 12/44). The trial was registered with the National Institute of Health (NIH) records on ClinicalTrials.gov website (NCT02292342). 2.2. Volunteers recruitment Female were not taken in part in this clinical trial because of the hormonal and vascular fluctuations due to their periods. A total of 20 male individuals were recruited (Fig. 1A) to voluntarily participate in the trial via poster advertisement at the University of Reading and surrounding area. All volunteers on the study were recruited under the supervision of a qualified research nurse, alongside trained researchers. Volunteers were assessed for health status using a standard health & lifestyle questionnaire and recruited on the basis of their compliance to the inclusion and exclusion criteria for the trial. Inclusion criteria: signed consent form, male aged 18e40 years, non-smoker, absence of metabolic (e.g. diabetes) and cardiovascular-related disorders (no pre-existing CVD and/or previous incidents), normal blood pressure (˂140/ 90 mm Hg) and hematological parameters (liver enzymes, heamoglobin, hematocrit and leukocyte counts). Exclusion criteria: individuals who were or had administered medication (including anti-inflammatory, antibiotics or blood pressure lowering medication) or nutritional supplements (including vitamin, mineral and fish oil supplements) within 2 months prior to the trial start date. Vegetarians/vegans and individuals with an extreme exercise routine were also excluded on the basis of their regular diet and activity. Throughout the trial period (including during washout), volunteers were asked to maintain their normal diet, activity and fluid intake. Twenty four hours prior to a study day visit volunteers were asked to restrict their diet to low polyphenol-containing foods, including fruit, vegetables, cocoa, chocolate, tea and wine and to avoid intake of nitrate-rich foods/beverages such as leafy green vegetables, beetroot, processed meat and tap water (rich source of nitrate in UK). They were also asked to restrict vigorous exercise to <20 min per day and the consumption of alcohol to <168 g alcohol per week (14 arbitrary units in UK). A low-fat, lowpolyphenol meal was also provided to all volunteers the evening prior to each visit and were asked to consume this before 20:00 in order to allow for a 12 h overnight fast. 2.3. Interventions: highly purified (
)-epicatechin test drinks and study design To investigate the dose-dependent activity of (
)-epicatechin relative to vascular function in healthy males at and below 1 mg/kg BW, highly purified (99%), food-grade (
)-epicatechin (EC) was provided by (Yancui Import & Export Corporation Limited,  Research (Lausanne, Switzerland) ascerShanghai, China). Nestle tained its purity and safety for use in clinical human intervention trials. (
)-Epicatechin was stored at
80  C till use. The trial was a randomized, double-blind, placebo-controlled, crossover intervention with 4 treatment arms in which volunteers consumed a water-based test drink containing 0.1, 0.5 and 1.0 mg/kg BW of (
)-epicatechin or a control drink containing water only. Test drinks were prepared immediately before consumption by dissolution in low-nitrate drinking water at room temperature (3 mL/kg of BW) [18]. Volunteers were randomly allocated to each intake level of EC or the control treatment (water only) via a block

~o  n ME et al., Acute study of dose-dependent effects of (
)-epicatechin on vascular function in healthy male Please cite this article as: Alan volunteers: A randomized controlled trial, Clinical Nutrition, https://doi.org/10.1016/j.clnu.2019.03.041

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Fig. 1. A, Consort diagram; B, study protocol for the acute randomized, double-blind, placebo-controlled, crossover intervention trial investigating the vascular effects of (
)-epicatechin in healthy male subjects.

randomization method (A-D) (Fig. 1). All responsible parties involved in conduction of the trial and assessment of the study outcomes were blinded to treatment allocation, as well as the participating volunteers. In compliance with the study protocol, volunteers were required to attend the Hugh Sinclair Unit of Human Nutrition on 4 separate occasions to assess each treatment during a 6 h time course where they were randomized to a treatment schedule via a block randomization system (Fig. 1B). 2.4. Experimental visits On arrival to the Nutrition Unit, the weight of each volunteer was recorded to determine the precise amount (mg) of

(
)-epicatechin they will receive relative to the arm of the trial they were currently assigned to. Volunteers were cannulated (left arm) by a qualified research nurse and blood samples were collected in the fasted state to carry out plasma nitrite/nitrate and epicatechin metabolites analyses. Following a 30 min period of inactivity under temperature-controlled conditions (22e24  C), baseline FMD measurements of the brachial artery (primary outcome), peripheral blood pressure (systolic and diastolic BP), laser Doppler imaging with iontophoresis to measure cutaneous perfusion in response to acetylcholine and sodium nitroprusside (LDI) were carried out. Following baseline measurements, volunteers were orally administered test or control interventions (30 s max). Additional vascular measures including FMD and BP were conducted at 1, 2, 4 and 6 h

~o  n ME et al., Acute study of dose-dependent effects of (
)-epicatechin on vascular function in healthy male Please cite this article as: Alan volunteers: A randomized controlled trial, Clinical Nutrition, https://doi.org/10.1016/j.clnu.2019.03.041

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post intake and LDI at 2, 4 and 6 h after (
)-epicatechin ingestion. Blood samples were collected at 1, 2, 4 and 6 h after consumption. Volunteers received a small low-fat, low-flavonoid containing lunch 4.5 h post intervention. All volunteers followed a 14-day washout period between study days, where they were asked to adhere to their normal diet and exercise regime.

2.5. Vascular measurements 2.5.1. Flow-mediated dilatation FMD of the brachial artery was the primary end point measure of the study measured following standard guidelines [22] using an ALT Ultrasound HDI5000 system (ATL Ultrasound, UK), with a semiautomated computerized analysis system (Brachial Analyzer, Medical Imaging Applications-llc, IL, US). After 30 min supine rest in a quiet, air-conditioned room, the brachial artery was imaged longitudinally at 2e10 cm proximal to the antecubital fossa. Baseline images recorded for 60 s, after which a blood pressure cuff placed around the forearm was inflated to 220 mm Hg. After 2 min of occlusion, the pressure was rapidly released to allow reactive hyperemia, with image collection continuing for 5 min post release. A single, fully trained researcher, who was blinded to the intervention details, analyzed all image files and peak diameter was defined as the maximum diameter obtained after the occlusion was released. FMD response was calculated as relative diameter change from baseline as compared to peak diameter during hyperemia and presented as percentage change.

2.5.2. Laser Doppler imaging Laser Doppler imaging combined with iontophoresis of an endothelium-dependent vasodilator, acetylcholine chloride (ACh) and an endothelium-independent vasodilator, sodium nitroprusside (SNP) was carried out as previously described [23] to give access to subcutaneous capillaries vasodilation. Ach and SNP were provided by Sigma Chemical Co (Poole, Dorset, UK) and both solutions were prepared at 1% with NaCl (0.5%). Ach solution was stored at 4  C and use within 7 days, meanwhile SNP solution was freshly prepared daily and stored at 4  C. Due to the light sensitive, SNP solution was store in dark until immediately before use. Measurements were taken on the forearm of the same arm where FMD measurement was done after 30 min of acclimatization in a supine position in a quiet, temperature controlled room (22e24  C). To control the spatial variability, the measurement tried to be done in the same location throughout the 4 visits at 10 cm from volunteer's wrist. Following basal measurement of skin perfusion, an incremental constant current was delivered in 5 mA steps (5, 10, 15 and 20 mA) to yield a total charge of 8 milliCoulombs within 12 min. A total of 20 scans were performed.

2.5.3. Systolic and diastolic blood pressure Systolic and diastolic blood pressure measures were performed automatically using an Omron, MX2 digital upper-arm blood pressure monitor (Omron Electronics Ltd, Milton Keynes, UK). Volunteers were previously rested in the supine position for approximately 30 min, during FMD measurement, and required to remain in this position or become semi-recumbent during repeated measures. Blood pressure readings were taken every 2 min until 3 successful readings were obtained, according to consistency. The average of these readings were calculated in excel and reported as mean and SEM. 2.6. Biochemical analyses Blood samples were drawn from volunteers (Fig. 1) via an in situ cannula and blood vacutainer system into EDTA (flavanol metabolite analysis) and sodium heparin (nitrite/nitrate analysis). Samples were collected on ice and immediately centrifuged (1700 g; 15 min at 4  C) and plasma aliquots of 1 mL were frozen at
80  C until analysis. Plasma stored for metabolite analysis and nitrate/ nitrite analysis were treated with ascorbic acid (200 mg/mL; 5% v/v) and nitrite preservation solution (100 mM N-ethylmaleimide, NEM), respectively. 2.6.1. Plasma (
)-epicatechin metabolite analysis Analysis of total plasma (
)-epicatechin metabolites (TPEM) was performed as previously described [24]. Target compounds were (
)-epicatechin-30 -sulfate, (
)-epicatechin-40 -sulfate, 0 (
)-epicatechin-5 -sulfate, (
)-epicatechin-70 -sulfate, (
)-epicatechin-30 -b-D-glucuronide, (
)-epicatechin-40 -b-D-glucuronide, 30 -O-methyl-(
)-epicatechin 40 -sulfate, 30 -O-methyl-(
)-epi0 0 catechin 5 -sulfate, 3 -O-methyl-(
)-epicatechin 70 -sulfate, 40 -Omethyl-(
)-epicatechin 50 -sulfate, 40 -O-methyl-(
)-epicatechin 70 sulfate. Some standars were provided by AtlanChim Pharma (SaintHerblain, France) and others were produced by complete chemical  Research Center. Quantification for those synthesis at the Nestle target compounds for which no standards were available was performed using the most similar standard as is shown in Table 1. Plasma samples (200 ml) were thawed on ice and spiked with internal standards. After protein precipitation, samples were filtered, washed with 200 ml methanol and dried at room temperature under a flow of nitrogen. Finally, the residue was dissolved in 100 ml of 8% acetonitrile in acidified water. Half of the volume was directly injected into the ultraperformance liquid chromatography UPLC-ESI-MS/MS system for quantification of total (
)-epicatechin metabolites which were separated by reversed-phase UPLC using a C18-column Acquity UPLC HSS(2.1 mm  100 mm, 1.8 mm), (Waters AG, Baden-D€ attwil, Switzerland) following the chromatographic method described by Actis-Goretta et al. [24]. Data were collected and processed using Analyst software (AB Sciex Switzerland GmbH,

Table 1 Compounds of plasma (
)-epicatechin metabolite analysis. Target Compounds

Standards used for quantification

(
)-epicatechin-30 -sulfate (
)-epicatechin-40 -sulfate (
)-epicatechin-50 -sulfate (
)-epicatechin-70 -sulfate (
)-epicatechin-30 -b-D-glucuronide (
)-epicatechin-40 -b-D-glucuronide 30 -O-methyl-(
)-epicatechin 40 -sulfate 30 -O-methyl-(
)-epicatechin 50 -sulfate 30 -O-methyl-(
)-epicatechin 70 -sulfate 40 -O-methyl-(
)-epicatechin 50 -sulfate 40 -O-methyl-(
)-epicatechin 70 -sulfate

(
)-epicatechin-30 -sulfate (
)-epicatechin-40 -sulfate (
)-epicatechin-30 -sulfate (
)-epicatechin-30 -sulfate (
)-epicatechin-30 -b-D-glucuronide (
)-epicatechin-40 -b-D-glucuronide 30 -O-methyl-(
)-epicatechin 40 -sulfate 30 -O-methyl-(
)-epicatechin 40 -sulfate 30 -O-methyl-(
)-epicatechin 40 -sulfate 30 -O-methyl-(
)-epicatechin 40 -sulfate 30 -O-methyl-(
)-epicatechin 40 -sulfate

~o  n ME et al., Acute study of dose-dependent effects of (
)-epicatechin on vascular function in healthy male Please cite this article as: Alan volunteers: A randomized controlled trial, Clinical Nutrition, https://doi.org/10.1016/j.clnu.2019.03.041

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C/o Applied Biosystems Europe BV, Zug, Switzerland). Each participants' samples were analyzed within a single assay batch in random sequence. The samples were analyzed blind.

Pearson's correlation coefficient to assess relationship between FMD and total plasma (
)-epicatechin metabolites (TPEM) during the timecourse.

2.6.2. Plasma nitrite and nitrate analysis Plasma levels of circulating nitrite and nitrate were individually assessed using an Eicom NOx Analyzer ENO-30 (San Diego, USA), a dedicated high-performance liquid chromatography (HPLC) system developed by Eicom Corporation (Japan). This system uses a postcolumn diazo coupling reaction (Greiss reaction) combined with HPLC using a NO-PAK separation column. The followed method was that proposed by Ishibashi et al. [25]. Nitrite and nitrate standard stock solutions were prepared in PBS buffer using sodium nitrite and sodium nitrate salts, respectively. On each day of analysis, a nitrite/nitrate working standard solution was prepared using the premade stock solutions and methanol. Eight calibration standards were prepared by series dilution containing nitrite and nitrate in the following concentrations: 1.6, 0.8, 0.4, 0.2, 0.1, 0.075, 0.05 and 0.025 mM and 100, 50, 25, 12.5, 6.25, 3.125 and 1.562 mM, respectively. After deproteinisation of plasma samples with methanol, 10 ml was injected into the HPLCsystem via a programmed autosampler (Waters, UK). The binary system phases were solvent A (carrier) and solvent B (reactor) with a flow rate of 330 ml/min and 100 ml/min, respectively. The nitrite present is able to react with the Griess reagent generating a red diazo compound, and absorbance is quantitatively measured by spectrophotometric detection at 540 nm. Furthermore, nitrate passing through the reduction column was reduced to nitrite prior to undergoing the same diazo coupling reaction. Calibration standards previously prepared were used for comparison with the peak areas of absorption produced by the test plasma samples in order to quantify the nitrite and nitrate present.

3. Results

2.7. Power calculation and statistical analysis A power calculation was performed for the primary endpoint measure of change in FMD response based on statistical limitations associated with this measure in order to determine an accurate minimum number of volunteers required to power the trial. The minimal statistically significant measurable improvement in FMD was set at an absolute change of 1.5% whilst considering a baseline vasodilation (FMD response) of 6.0%, based on previous clinical assumptions that the minimal statistically significant improvement detectably following drug/nutrient interventions is an absolute change in FMD of 1.5e2% [22] The sample size was calculated based on a variance of repeated measures of 1.8%, deduced from the interindividual variability analysis of data collected in a FMD pilot reproducibility study. This is consistent with previous, similar clinical trials that have used a standard deviation of 2.3% [9,18]. Using a standard deviation of 1.8%, a significance level of 0.05 and a power of 80% a total of 18 volunteers were required to observe significant within-subject differences between treatments of at least 1.5%. Therefore, assuming a dropout rate of 10% we aimed to recruit 20 volunteers in total. All results were expressed as means ± standard error of the mean (SEM), and further statistically analyzed using GraphPad Prism version 5 software (Graphpad Software Inc. San Diego, CA, USA). Two-factor repeated measures ANOVA was utilized to assess time course data for study endpoint outcomes in order to estimate intra-individual treatment effects, with pair wise comparisons corrected using the Bonferroni test during post-hoc analysis. Statistical significance was assumed if a null hypothesis could be rejected at p ˂ 0.05. LDI results were expressed as area under the cure (AUC) and incremental AUC (iAUC) calculated using the trapezoidal method. A correlation analysis was performed using

3.1. Baseline characteristics of sample population The characteristics of the study population are detailed in Table 2. Baseline characteristics and mean values for parameters were all within the normal range for healthy individuals. The (
)-epicatechin test drinks were well tolerated and no adverse advents were reported in the context of the study. 3.2. (
)-Epicatechin induced dose-dependent increases in vascular function Significant increases in % FMD were observed after ingestion of 0.5 mg/kg BW at 2 h (p < 0.01) and similarly at 1 h (p < 0.01) and 2 h (p < 0.001) following ingestion of the highest dose, 1.0 mg/kg BW. Significant differences in FMD were also identified between the highest (
)-epicatechin dose (1.0 mg/kg BW) and the lowest (
)-epicatechin dose (0.1 mg/kg BW) at 1 h (p < 0.05) and 2 h (p < 0.01) after consumption of the test drinks (Fig. 2). Peak vasodilation occurred at 2 h after treatments (0.5 and 1.0 mg/kg BW), with subsequent declines in FMD response towards baseline at 4 and 6 h. FMD response (endothelium-dependent brachial artery vasodilation) increased after ingestion of all 3 (
)-epicatechin test

Table 2 Baseline clinical characteristics of the study population (n ¼ 20). Baseline characteristics

Mean ± SEM

Age (years) BMI (Kg/m2) Total cholesterol (mmol/L) Triacylglycerol (mmol/L) SBP (mm Hg) DBP (mm Hg) Brachial diameter (mm) FMD (%)

23.4 ± 1.30 23.2 ± 1.51 4.53 ± 0.15 1.00 ± 0.08 124 ± 1.19 66 ± 1.14 3.93 ± 0.08 5.89 ± 0.25

BMI, body mass index; SBP, systolic blood pressure; DBP, diastolic blood pressure; FMD, flow-mediated dilation.

Fig. 2. Timecourse of FMD (mean ± SEM) after consumption of (
)-epicatechin test drinks containing 1.0, 0.5, 0.1 mg/kg BW and control drink (water only) (n ¼ 20). Data was analyzed using a 2-factor repeated measures ANOVA with time and treatment as the two factors, [significant effects of time (p ¼ 0.0001), treatment (p ¼ 0.0007) and the interaction (p ¼ 0.0108)]. Post hoc analyses were conducted using a Bonferroni multiple comparisons test. **,***,y,yy Significantly different compared to control drink and time effect compared to 0 h: **p < 0.01, ***p < 0.001 and compared to 0.1 mg/kg BW (
)-epicatechin drink: yp < 0.05, yyp < 0.01. FMD, flow-mediated dilatation; EC, (
)-epicatechin.

~o  n ME et al., Acute study of dose-dependent effects of (
)-epicatechin on vascular function in healthy male Please cite this article as: Alan volunteers: A randomized controlled trial, Clinical Nutrition, https://doi.org/10.1016/j.clnu.2019.03.041

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drinks administered to volunteers in a dose-dependent manner between 1 and 2 h (Fig. 2). The magnitude of increase from baseline (0 h) to 1 h was 1.6 ± 0.3% following (
)-epicatechin (1.0 mg/kg BW), and at 2 h FMD increased by 1.2 ± 0.3% and 2.9 ± 0.3% after ingestion of 0.5 mg/kg and 1.0 mg/kg BW (
)-epicatechin, respectively. No significant changes in FMD were observed at baseline (0 h), 4 h and 6 h and neither at any time-point following intake of 0.1 mg/kg BW (
)-epicatechin and the control. Both LDI (Fig. 3) and BP (Fig. 4) measures were not significantly altered after consumption of any of the (
)-epicatechin dose intakes compared with baseline or the control drink.

3.3. Relationship of FMD to plasma (
)-epicatechin metabolites and NOx Mean plasma concentrations of epicatechin metabolites ranged from 0.19 to 9.93 mmol/L following consumption of highly purified (
)-epicatechin treatments (excluding control) up to 6 h. The time course for the appearance of flavanol metabolites in the circulation paralleled FMD data, although in all cases peak metabolite concentrations preceded peak FMD (Figs. 2 and 5) at 1 h. Results indicated significant increases in plasma flavanol metabolites following ingestion of 0.5 and 1.0 mg/kg BW (
)-epicatechin at 1 h (p < 0.001), 2 h (p < 0.001) and 4 h (p < 0.01 and p < 0.001, respectively) and additionally at 6 h (p < 0.01) for 1.0 mg/kg BW (
)-epicatechin (Fig. 5). Total plasma concentrations of (
)-epicatechin metabolites were at or below the limit of detection (0.01 mmol/L) for the control at all time points and for the lowest intake at 4 and 6 h. Analysis using Pearson's correlation coefficient found positive associations within take amount between % FMD response and TPEM at 1 h and 2 h. At 1 h, coefficients between % FMD and TPEM were R2 ¼ 0.010, R2 ¼ 0.013 and R2 ¼ 0.174, for 0.1, 0.5 and 1.0 mg/kg BW (
)-epicatechin, respectively. At 2 h correlation coefficients with TPEM were R2 ¼ 0.07 and R2 ¼ 0.206 for the 0.5 and 1.0 mg/kg BW (
)-epicatechin, respectively. On the other hand, no significant increases in plasma nitrite, nitrate or NOx at any timepoint during the crossover intervention comparative to baseline and control measures (p > 0.05) (Fig. 6).

Fig. 4. Timecourse of systolic (A) and diastolic (B) blood pressure (mean ± SEM) after consumption of (
)-epicatechin test drinks containing 1.0, 0.5, 0.1 mg/kg BW and control drink (n ¼ 20). No significant differences were found between control and test drinks at baseline and post-intervention (1, 2, 4 and 6 h). BP, blood pressure.

4. Discussion Previous works focused on the beneficial vascular effects of cocoa has predominantly centered on the physiological actions of the total flavanol content [3e10,19]. However, although (
)-epicatechin seems to be the main responsible compound for vascular effect, a direct cause and effect relationships between intake and efficacy are difficult to establish following the consumption of

Fig. 3. Time-course of AUC and IAUC (mean ± SEM) for measures of LDI (arbitrary perfusion units, PU) after consumption of (
)-epicatechin test drinks containing 1.0, 0.5, 0.1 mg/kg BW and control drink (n ¼ 20). No significant differences were found between control and test drinks at baseline and post-intervention (1, 2, 4 and 6 h). Ach, acetylcholine; SNP, sodium nitroprusside; AUC, area under the curve; iAUC, incremental area under the curve.

~o  n ME et al., Acute study of dose-dependent effects of (
)-epicatechin on vascular function in healthy male Please cite this article as: Alan volunteers: A randomized controlled trial, Clinical Nutrition, https://doi.org/10.1016/j.clnu.2019.03.041

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Fig. 5. Timecourse of total plasma (
)-epicatechin metabolites (TPEM) (mean ± SEM) after consumption of (
)-epicatechin test drinks containing 1.0, 0.5, 0.1 mg/kg BW and control drink (n ¼ 20). Data was analyzed using a 2-factor repeated measures ANOVA with time and treatment as the two factors, [significant effects of time (p < 0.0001), treatment (p < 0.0001) and the interaction (p < 0.0001)]. Post hoc analyses were conducted using a Bonferroni multiple comparisons test. **,*** Significantly different compared to control drink: **p < 0.01 ***p < 0.001. EC, (
)-epicatechin; TPEM, total plasma (
)-epicatechin metabolites.

complex food matrices such as cocoa. Therefore, a proof of concept study with highly purified (
)-epicatechin was performed, providing insight, for the first time, into the dose-dependent effect of its vasoactive benefits post intake and insights into the circulating metabolites and nitric oxide pool that might mediate such effects. In response, this acute crossover intervention trial investigating the vascular effects of (
)-epicatechin provided further evidence for the increase vascular function of this compound, and in particular the impact on FMD % response of the brachial artery for a population of young, healthy males with no cardiovascular dysfunction. In agreement with our data, the oral administration of highly purified (
)-epicatechin in a human intervention causally linked to the increase of FMD % [18], contrary to other studies which suggested that (
)-epicatechin represents a compound with cardiovascular health benefits [19]. Data shows clear dose-dependent increases in FMD following (
)-epicatechin interventions, and specifically at 1 h and 2 h after ingestion of the middle dose (0.5 mg/ kg BW) and highest dose (1.0 mg/kg BW), where increasing magnitude and statistical significance was observed, respectively. However, after conducting post-hoc power calculations for the lower dose treatment, 0.1 mg/kg BW, no significant variations were observed in comparison with those FMD % values for control treatment. Until now, the minimum dose of (
)-epicatechin proven to be vascular active was 1 mg/kg BW [18]. Our results evidence that the ingestion of lower doses, 0.5 mg/kg BW, is enough to induce a physiologically increase in FMD %. Currently, evidence of a significant increase in FMD with an intervention dose as low as 0.5 mg/kg (
)-epicatechin BW has not been directly reported, and therefore provides much needed dose-related insight regarding active and minimum-active doses capable of inducing acute improvements in FMD, within a healthy male population. Translating this information into practical issues, 41 commercial milk and dark chocolates were previously analyzed by our research group [26]. The mean flavanol content for milk and dark chocolates were 0.703 and 1.156 mg/g respectively being epicatechin the predominant flavanol. In respect of this evidence and our FMD results, consumption of approximately 57 g of milk chocolate and less than 35 g of dark chocolate for a healthy male of 80 kg would provide the minimum-active dose to support both statistically and clinically significant improvements in FMD. However, despite the great responsiveness observed at the macrovessels (FMD), no effect were found on microvessels (LDI)

Fig. 6. Timecourse of plasma nitrite (A), plasma nitrate (B) and plasma NOx (C) (mean ± SEM) after consumption of (
)-epicatechin (EC) test drinks containing 1.0, 0.5, 0.1 mg/kg BW and control drink (n ¼ 20). No significant differences were found between control and test drinks at baseline and post-intervention (1, 2, 4 and 6 h). NOx, total nitrite and nitrate.

after epicatechin treatment. This discrepancy between micro and macrovessels response to (
)-epicatechin can be attributable to several factors. Recently, it is stated that protocols that used multiple pulses to deliver the electrical current may have mediated a vascular response that is more influenced by non-specific vasodilator effects than which delivers continuous stimulation [27]. The fact that FMD was performed just before LDI measurement on the same arm, may have also masked the subsequent response to ACh and SNP due to the shear-stress induced vasodilation from occlusion-reperfusion. On the other hand, it is also important to take into account the great intraindividual baseline variations. Based on bibliography, the amount of (
)-epicatechin tested could be also insufficient to drive an microcirculation increase. In a recent study, an increase of cutaneous microcirculation was elevated

~o  n ME et al., Acute study of dose-dependent effects of (
)-epicatechin on vascular function in healthy male Please cite this article as: Alan volunteers: A randomized controlled trial, Clinical Nutrition, https://doi.org/10.1016/j.clnu.2019.03.041

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about 1.7-fold at 2 h in healthy subjects after consumption of flavonol-rich cocoa drink (329 mg of flavanols of which 61 mg was epicatechin). Although this dose of (
)-epicatechin could look comparable to the highest dose tested in this study, it only supposed the 18% of the total flavanols-rich cocoa drink. Therefore, the microcirculation increase seemed to be not only to the (
)-epicatechin content but also to the effect of the rest of flavanols and their synergic effects. In contrast, no effects on microvessels were found after the ingestion of cocoa drink with lower flavanol content (27 mg of flavanols of which 6.6 mg was epicatechin) [28]. On the other hand, a chronic study revealed that flavanol-rich cocoa consumption entailed no vasodilator responses to Ach and SNP in patients with established coronary artery disease [29]. From baseline mean FMD % reach the maximal change two hours after treatment ingestion at 0.5 and 1.0 mg/kg BW doses which is consistent with the timecourse of total plasma (
)-epicatechin metabolites (TPEM). This fact suggests that there is an optimal level of circulating (
)-epicatechin metabolites for driving physiological effect on the endothelium after two hours of treatment ingestion. Other studies also reported intake-dependent improvements in FMD paralleled with appearance of individual phenolic plasma metabolites following an intervention of flavanolrich food such as blueberry, cocoa or coffee, showing the highest level after 2 h ingestion [18,30,31]. (
)-Epicatechin-30 -b-D-glucuronide, (
)-epicatechin-30 -sulfate, and 30 -O-methyl-(
)-epicatechin-5-sulfate have been reported as the major in vivo metabolites present in the bloodstream at 1e3 h after ingestion of cocoa, chocolate products, or pure compounds [24,32,33]. Potential mechanisms by which such circulating metabolites mediate their vascular effects have been postulated, and include their potential to inhibit NADPH oxidase, thus affecting superoxide production and subsequent NO bioavailability at the vascular epithelium [30,34,35]. Because of the fact that FMD is mediated by NO, increases in NOS activity are paralleled by increases in plasma nitroso species. Results emanated from other studies establish a causal link among parallel measurements of FMD and circulating NO species. These facts in conjunction with NOS inhibition studies after oral ingestion of flavanol represents a mechanistically strong experiment framework [9,18,36,37]. However, nitrite and nitrate are claimed not to be the best markers for NO bioavailability by other authors. It is yet unclear if plasma nitrite can indicate acute changes in NOS activity in health humans, meanwhile plasma nitrate levels do not reflect acute changes in endothelial NOS activity since it is known to be influenced by a variety of NOS independent factors [38]. Particularly, our data do not reveal significant enhancements in plasma nitrite, nitrate or NOx at any timepoint during the crossover intervention. This fact supports that neither nitrite, nitrate nor NOx are reliable markers of acute changes endothelial NOS activity and/or that (
)-epicatechin acts on endothelial function via other mechanisms than NO (e.g. via a decrease in angiotensin II and an inhibition of endothelin-1 [39]). In conclusion our findings support the notion that (
)-epicatechin, and consequently its subsequent metabolites, are an important mediator of the cardiovascular effects of flavanols rich food. A clearer picture of dose-dependency of (
)-epicatechin is drawn since our data adds new evidence demonstrating significant activity from as low as 0.5 mg/kg BW (
)-epicatechin, with increasing magnitude and significance to the highest dose intervened in the trial. Although, data from this acute study cannot be used to determine the long term effects of repeated consumption of (
)-epicatechin on vascular function and the study population is limited to healthy young males, findings in the current paper may provide new avenues to dietary or therapeutic interventions aimed at improving and maintaining cardiovascular health.

State of authorship JPES was the principal investigator, PI, of the study, MEA was a postdoctoral researcher, MSC was pre-doctoral student assigned to the project, GS was a PhD student collaborator. JPES, MEA and MSC designed the study. MEA, MSC and GS conducted the epicatechin study. JPES, MEA and MSC collaborated on the manuscript preparation. LAG, AL LP are employees of the Nestec SA. AL and LP performed the analysis of the plasma samples for epicatechin metabolites measurement. All authors read and approved the final manuscript. Conflict of interest No conflicts of interest are stated by the authors. Acknowledgments This work was supported by a Biotechnology and Biological Q2 Sciences Research Council, DRINC grant (BB/L02540X/1) and an ~o n thank the UniIndustrial CASE grant (BB/J500896/1). ME Alan versity of Castilla-La Mancha for the postdoctoral contract: Access to the Spanish System of Science, Technology and Innovation (SECTI). Appendix A. Supplementary data Supplementary data to this article can be found online at https://doi.org/10.1016/j.clnu.2019.03.041. References [1] Kris-Etherton PM, Keen CL. Evidence that the antioxidant flavonoids in tea and cocoa are beneficial for cardiovascular health. Curr Opin Lipidol 2002;13: 41e9. [2] Hollenberg NK, Fisher NDL, McCullough ML. Flavanols, the Kuna, cocoa consumption, and nitric oxide. J Am Soc Hypertens 2009;3:105e12. [3] Hooper L, Kay C, Abdelhamid A, Kroon PA, Cohn JS, Rimm EB, et al. Effects of chocolate, cocoa, and flavan-3-ols on cardiovascular health: a systematic review and meta-analysis of randomized trials. Am J Clin Nutr 2012;95:740e51. [4] Shrime MG, Bauer SR, McDonald AC, Chowdhury NH, Coltart CE, Ding EL. Flavonoid-rich cocoa consumption affects multiple cardiovascular risk factors in a meta-analysis of short-term studies. J Nutr 2011;141:1982e8. [5] Hollenberg NK. Vascular action of cocoa flavonols in humans: the roots of the story. J Cardiovasc Pharmacol 2006;47:S99e102. [6] Heiss C, Schroeter H, Balzer J, Kleinbongard P, Matern S, Sies H, et al. Endothelial function, nitric oxide, and cocoa flavanols. J Cardiovasc Pharmacol 2006;47:S128e35. discussion S172e126. [7] Balzer J, Rassaf T, Heiss C, Kleinbongard P, Lauer T, Merx M, et al. Sustained benefits in vascular function through flavanol-containing cocoa in medicated diabetic patients: a double-masked, randomized, controlled trial. J Am Coll Cardiol 2008;51:2141e9. [8] Flammer AJ, Sudano I, Wolfrum M, Thomas R, Enseleit F, Periat D, et al. Cardiovascular effects of flavanol-rich chocolate in patients with heart failure. Eur Heart J 2012;33:2172e80. [9] Heiss C, Kleinbongard P, Dejam A, Perre S, Schroeter H, Sies H, et al. Acute consumption of flavanol-rich cocoa and the reversal of endothelial dysfunction in smokers. J Am Coll Cardiol 2005;46:1276e83. [10] Heiss C, Finis D, Kleinbongard P, Hoffmann A, Rassaf T, Kelm M, et al. Sustained increased in flow-mediated dilation after daily intake of high-flavonol cocoa drink over 1 week. J Cardiovasc Pharmacol 2007;49:74e80. [11] Berry N, Davison MK, Coates AM, Buckley JD, Howe PR. Impact of cocoa flavanol consumption on blood pressure responsiveness to exercise. Br J Nutr 2010;103:1480e4. [12] Vlachopoulos C, Aznaouridis K, Alexopoulos N, Economou E, Andreadou I, Stefanadis C. Effect of dark chocolate on arterial function in healthy individuals. Am J Hypertens 2005;18:785e91. [13] Hermann F, Spieker L, Ruschitzka F, Sudano I, Hermann M, Binggeli C, et al. Dark chocolate improves endothelial and platelet function. Heart 2006;92: 119e20. [14] Monahan KD, Feehan RP, Kunselman AR, Preston AG, Miller DL, Lott ME. Dosedependent increases in flow-mediated dilation following acute cocoa ingestion in healthy older adults. J Appl Physiol 2011;111:1568e74. [15] Heiss C, Dejam A, Kleinbongard P, Schewe T, Sies H, Kelm M. Vascular effects of cocoa rich in flavan-3-ols. JAMA 2003;290:1030e1.

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)-epicatechin on vascular function in healthy male Please cite this article as: Alan volunteers: A randomized controlled trial, Clinical Nutrition, https://doi.org/10.1016/j.clnu.2019.03.041

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